Temperature-controlled microintaglio printing for high-resolution micropatterning of RNA molecules

We have developed an advanced microintaglio printing method for fabricating fine and high-density micropatterns and applied it to the microarraying of RNA molecules. The microintaglio printing of RNA reported here is based on the hybridization of RNA with immobilized complementary DNA probes. The hy...

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Veröffentlicht in:	Biosensors & bioelectronics 2015-05, Vol.67, p.115-120
Hauptverfasser:	Kobayashi, Ryo, Biyani, Manish, Ueno, Shingo, Kumal, Subhashini Raj, Kuramochi, Hiromi, Ichiki, Takanori
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Sprache:	eng
Schlagworte:	Base Sequence Beads Biosensing Techniques Biosensors Demand Density Deoxyribonucleic acid DNA, Complementary - chemistry DNA, Complementary - genetics High density Nucleic Acid Hybridization Oligonucleotide Array Sequence Analysis Printing Ribonucleic acids RNA - chemistry RNA - genetics Wells
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creator	Kobayashi, Ryo Biyani, Manish Ueno, Shingo Kumal, Subhashini Raj Kuramochi, Hiromi Ichiki, Takanori
description	We have developed an advanced microintaglio printing method for fabricating fine and high-density micropatterns and applied it to the microarraying of RNA molecules. The microintaglio printing of RNA reported here is based on the hybridization of RNA with immobilized complementary DNA probes. The hybridization was controlled by switching the RNA conformation via the temperature, and an RNA microarray with a diameter of 1.5 µm and a density of 40,000 spots/mm(2) with high contrast was successfully fabricated. Specifically, no size effects were observed in the uniformity of patterned signals over a range of microarray feature sizes spanning one order of magnitude. Additionally, we have developed a microintaglio printing method for transcribed RNA microarrays on demand using DNA-immobilized magnetic beads. The beads were arrayed on wells fabricated on a printing mold and the wells were filled with in vitro transcription reagent and sealed with a DNA-immobilized glass substrate. Subsequently, RNA was in situ synthesized using the bead-immobilized DNA as a template and printed onto the substrate via hybridization. Since the microintaglio printing of RNA using DNA-immobilized beads enables the fabrication of a microarray of spots composed of multiple RNA sequences, it will be possible to screen or analyze RNA functions using an RNA microarray fabricated by temperature-controlled microintaglio printing (TC-µIP).
doi_str_mv	10.1016/j.bios.2014.07.050
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The microintaglio printing of RNA reported here is based on the hybridization of RNA with immobilized complementary DNA probes. The hybridization was controlled by switching the RNA conformation via the temperature, and an RNA microarray with a diameter of 1.5 µm and a density of 40,000 spots/mm(2) with high contrast was successfully fabricated. Specifically, no size effects were observed in the uniformity of patterned signals over a range of microarray feature sizes spanning one order of magnitude. Additionally, we have developed a microintaglio printing method for transcribed RNA microarrays on demand using DNA-immobilized magnetic beads. The beads were arrayed on wells fabricated on a printing mold and the wells were filled with in vitro transcription reagent and sealed with a DNA-immobilized glass substrate. Subsequently, RNA was in situ synthesized using the bead-immobilized DNA as a template and printed onto the substrate via hybridization. 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The microintaglio printing of RNA reported here is based on the hybridization of RNA with immobilized complementary DNA probes. The hybridization was controlled by switching the RNA conformation via the temperature, and an RNA microarray with a diameter of 1.5 µm and a density of 40,000 spots/mm(2) with high contrast was successfully fabricated. Specifically, no size effects were observed in the uniformity of patterned signals over a range of microarray feature sizes spanning one order of magnitude. Additionally, we have developed a microintaglio printing method for transcribed RNA microarrays on demand using DNA-immobilized magnetic beads. The beads were arrayed on wells fabricated on a printing mold and the wells were filled with in vitro transcription reagent and sealed with a DNA-immobilized glass substrate. Subsequently, RNA was in situ synthesized using the bead-immobilized DNA as a template and printed onto the substrate via hybridization. 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source	MEDLINE; Elsevier ScienceDirect Journals
subjects	Base Sequence Beads Biosensing Techniques Biosensors Demand Density Deoxyribonucleic acid DNA, Complementary - chemistry DNA, Complementary - genetics High density Nucleic Acid Hybridization Oligonucleotide Array Sequence Analysis Printing Ribonucleic acids RNA - chemistry RNA - genetics Wells
title	Temperature-controlled microintaglio printing for high-resolution micropatterning of RNA molecules
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